Lacrimal System 3.pdf

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Lacrimal System
Karen Gil MD, MHSN.

Development
• Nasolacrimal system
– Lacrimal gland, lacrimal
sac, canaliculi
nasolacrimal duct,
caruncle from surface
ectoderm

4.5 months

Tear Film
• 7 to 10 μm thick
• Three layers
– Lipid layer
– Aqueous layer
– Mucous layer

Tear Film
• Functions:
– Keep the surface moist and serves as a lubricant between
the globe and eyelids
– Traps debris and helps remove sloughed epithelial cells
and debris
– Primary source of atmospheric oxygen for the cornea
– Provides a smooth refractive surface necessary for
optimum optical function
– Contain antibacterial substances (lysozyme, beta-lysyn,
lactoferrin, IgA)
– Help maintain corneal hydration
– Contains growth factors and peptides that can regulate
ocular surface wound and repair

Tear Film
• 3 layers:
1. Lipid layer
– 1% of the thickness of the
tear film
(Meibomian and Zeiss
glands)
• Waxy esters
• Cholesterol
• Free fatty acids

– Function:
• retards evaporation and
provides lubrication for
smooth eyelid movement
• Provides stability to the
tear film

Tear Film
2. Aqueous layer
– 60-70% total tear film
(main and accessory lacrimal
glands)
• Water
• Electrolytes (Na+,K+Mg2+, Ca2+, Cl-,
HCO3, PO4)
• Inorganic salts
• Glucose
• Urea
• Enzymes
• Immunoglobulins (A,G,D,E,M)
• Cytokines
• Proteins
• Peptide growth factors
• Glycoproteins
• Antibacterial substances (lysozyme,
lactoferrin and lipocalin, Beta-lysin,
defensins)
• Vitamins

Tear Film
3.

Mucous Layer (conjunctival
goblet cells)
• 30-40% total tear film
–

–

–

Composed of glycocalyx of
the ocular surface epithelia
and mucin produced and
secreted by the conjunctival
goblet cells
Acts as an interface that
facilitate adhesion of the
aqueous layer to the ocular
surface
Mucin also bind and entrap
bacteria and viruses blocking
binding sites on microbes and
prevents them penetrating to
the ocular surface

Tear Film Stability
• The eyelids spread the mucous layer evenly
over the corneal epithelium
• Corneal epithelium accept this mucous and
encompasses the aqueous film because of the
glucocalix secreted form the corneal epithelial
cells
• This sugar layer overlies the corneal
epithelium and absorbs the mucous creating a
hydrophilic surface to accept the tears

Total Volume of Tears
• Total volume of tears on the ocular surface is 7
to 10 μl
• Normal tear production is about 1 μl/min
• Average in an eye drop contains 50 μl
• The eye can only hold 20-30 μl at once

Properties of the Tears
• Normally the tear film is isotonic in comparison
to the cornea
• Electrolytes in the aqueous layer –
– Na+ and Cl- ions contribute in the osmolality of the
tear film
– Calcium is essential for hemidesmosome formation in
the basement membrane of the corneal epithelium (in
excess in contact lenses users decrease acuity)
– Potassium found in high concentrations is important
in maintaining the health of the corneal epithelium

Tear Film and Cornea

Properties of the Tears

(salt

content

• Normal osmolarity around 315 mOsm/kg
• Electrolytes are responsible for the osmolarity
• Vary depending in :
–
–
–
–

Blink rate
Humidity
Ocular pathology ~
Contact lenses
~

w

-

barrier

UI

tear films

:

cornea

• Dry eye syndrome can cause increase tear osmolarity
• TX with hypotonic eye drops (osmolarity 150
mOsm/kg) decrease osmolarity
-

a

of te

Properties of the Tear Film
• Average pH is 7.45
• Tears had good buffering ability , so allow the
eye tolerate ophthalmic solutions with
different pH 3.5-10.5
• During sleep the tears become more acidic
• Most eye drops are weak bases to allow better
absorption

Lacrimal Secretory System
The lacrimal system has a
dual function:
• secretory component
– contributing to the
formation of tears

• excretory component
– provides a conduit
though which tears drain
from the eye into the
nose

Lacrimal Secretory System
• Includes:
– Main lacrimal gland
– Accessory lacrimal
glands (Krause and
Wolfring)
– Meibomian glands
– Conjunctival goblet cells

Lacrimal Gland
Lacrimal gland
• Located in the temporal
fossa of the orbital plate
of the frontal bone
• Posterior to the superior
orbital margin
• Two portions or lobes
(divided by the
aponeurosis of the
levator muscle):
– Palpebral (inferior)
– Orbital [superior)

Lacrimal Gland
Orbital portion lacrimal gland
• Larger
• Almond shaped
• Superior surface lies against
the periorbita of the
lacrimal fossa
• Inferior surface lies against
the aponeurosis
• Medial edge lies against the
levator muscle
• Lateral edge lies the lateral
rectus muscle

Lacrimal Gland
Palpebral portion of the
lacrimal gland
• ⅓ to ½ the size of the
orbital lobe
• Subdivided in 2 o3 section
• Lacrimal gland can be seen
when you evert the upper
eyelid
• Ducts from both portions of
the lacrimal gland exit
thought the palpebral lobe

Lacrimal Gland
• Lacrimal gland consist
of lobules made of
numerous acini
• Acini
– is an irregular
arrangement of
secretory cells around a
central lumen
surrounded by an
incomplete layer of
myopeithelial cells

Lacrimal Gland
• A network of ducts
connects the acini and
drains into one of the
main excretory ducts
• Approximately 12 ducts
that empty in the
conjunctival sac in the
superior fornix

Lacrimal Gland
• Secretion is composed of:
– Water
– Electrolytes
– Antibacterial agents
(lysozyme, lactoferrin and
immunoglobulins)

• Reflex secretion
– Increases the volume in
response to a stimulus
– Both main and accessory
glands play a role

Blood Supply
• Lacrimal Gland
• Blood supplied by the
lacrimal artery (branch
of the ophthalmic
artery)

Innervation
• Lacrimal gland
– Sensory innervation by
the lacrimal nerve
(branch of ophthalmic
branch of Trigeminal
nerve)
– Receives vasomotor
sympathetic innervation
and secretomotor
parasympathetic
innervation

Blood Supply and Innervation
• Reflex tearing –
– Occurs by stimulation of
branches of the
ophthalmic division in
response to external
stimuli (intense light)
– Afferent pathway is by
the trigeminal nerve
– Parasympathetic
pathway is though the
facial nerve

Tear Film Distribution
• Lacrimal gland fluid is secreted
into the lateral part of the
upper fornix
• Descends across the anterior
surface of the globe
• Contraction of the orbicularis
forces meibum out of the
pores and lid motion can
spread the thin lipid layer
across the surface
• Each blink reforms the tear
film, spreading into over the
ocular surface
DES

will

have

smaller meniscus

Lacrimal

I

pool

(From Zide BM, Jelkes G. Surgical Anatomy of the Orbit. New York: Raven
Press, 1985.)

of fear

film

Tear Film Distribution
• Both upper and lower
eyelid margins have a tear
meniscus
• Upper tear meniscus
continuous with the
lower meniscus at the
lateral canthus and
medial canthus
• In the medial canthus the
tear meniscus lead
directly to punctum and
drain in to them
(From Zide BM, Jelkes G. Surgical Anatomy of the Orbit. New York: Raven
Press, 1985.)

Nasolacrimal Drainage System
• 75% of the tear fluid
passes through the
nasolacrimal drainage
system
• 25% is evaporated or
reabsorbed through the
conjunctival tissue

Nasolacrimal Drainage System
• Consist in:
–
–
–
–

Lacrimal punctum
Canaliculi
Lacrimal sac
Nasolacrimal duct

Nasolacrimal Drainage System
Lacrimal Punctum
• Located in the lacrimal
papilla
• At the junction of the
lacrimal and ciliary portions
of the eyelid margin
• Both lower and upper
eyelids have punctum
• Normally is are turned
toward the globe
• Each one opens into a
lacrimal canaliculus

Nasolacrimal Drainage System
Canaliculi
• Tubes in the upper and
lower eyelids
• Join the punctum to the
lacrimal sac
• Walls of the canaliculi
contain elastic tissue and
surrounded by fibers of
the Horner’s muscle
(orbicularis muscle fibers)

Nasolacrimal Drainage System
Canaliculi
• First portion is vertical –
approximately 2mm
• Second portion is
horizontal
– Runs along the lid
margin approximately
8 mm

Nasolacrimal Drainage System
Canaliculi
• Both upper and lower
canaliculi join to form a single
common canaliculus (ampulla
of Maier)
• Piers the periorbita covering
the lacrimal sac and enters the
lateral aspect of the sac
• Enters in an angle that
produces a physiological valve
(Valve of Rosenmuller) that
prevents reflux, is the first
valve in the system

Lacrimal Sac
• Lies within the lacrimal fossa
• Formed by the fontal process
of the maxillary bone and the
lacrimal bone
• Sac is surrounded by fascia
that continues with the
periorbita
• The two limbs of the medial
palpebral ligament straddle
the sac to attach to the
posterior and anterior crests
• Orbital septum and the check
ligament of the medial rectus
muscle lie behind the lacrimal
sac

Lacrimal Sac
• Lacrimal Sac
– Fundus: 3-5 mm
↓ 14
– Body: 10 mm

• Lacrimal sac empties
into the nasolacrimal
duct

mm in

length

Nasolacrimal duct
• Lacrimal sac enters the
nasolacrimal canal in the
maxillary bone
• Nasolacrimal duct
– Interosseous part: 12 mm
– Meatal part: 5mm

• Drains to the inferior
meatus of the nose
• Valve of Hasner- mucosal
fold that prevents
retrograde movement of
fluid up from the nasal
cavity

Valves
• The mucous membrane within
the sac and nasolacrimal duct is
arranged into membranous folds
that act as valves
• Folds or Valves:
– Valve of Rosenmuller
• where the common canaliculus
enters into the sac

– Valve of Krause
• constrictions at the junction of the
sac in the nasolacrimal duct

– Valve of Hyrtl and valve of
Taillefer
• within the nasolacrimal duct

– Valve of Hasner (plica lacrimalis)
• at the end of the nasolacrimal duct
under the inferior turbinate

1. valve of Rosenmüller
2. valve of Krause
3. spiral valve of Hyrtl
4. valve of Taillefer
5. valve of Hasner or plica lacrimalis

Tear Drainage
1. Eyelid closure start at
the temporal canthus
and moves toward the
medial canthus
2. Tears pool in the
lacrimal lade
3. Tear menisci are
pushed toward the
lacrimal punctum
which they drain

Tear Drainage
4.

Contraction of the orbicularis
muscle pulls on the fascial
sheath attached to the lacrimal
sac, causes:
–
–
–
–

5.

Lateral displacement of the
lateral wall
Expanding the sac
Creating negative pressure within
it
Pulling tears in from the
canaliculus

Orbicularis relaxation
–
–
–

Lacrimal sac collapse
Tears are driven into the
nasolacrimal duct
Canaliculi open and act as
siphons to pull tears in through
the punctum

Tear Drainage
6. Tears drain into the
nasolacrimal duct
mainly by gravity
7. Some tear is absorbed
in the lining mucosa
and the remaining
tears enter to the
inferior meatus

Aging Changes
• Aging process –
–
–
–
–

eyelids tissue atrophies
The skin loses elasticity
Wrinkles appear
Distance between the
center of the pupil and
the lower margin
increases due to sagging
of the lower lid (more in
males)

Aging Changes
• Tearing causes:
– Eversion of the lower
punctum due to eyelid
position
– stenosis of the passages in
the lacrimal drainage
system
– Basal rate of tear secretion
diminishes after age 40
– Tear reflex decreases
– Goblet cells decrease
– Tear is more viscous don’t
flow easily

Tear Break Up Time
• Measure the stability of
the tear film
• Normal TBUT is between
15 and 45 seconds
• TBUT less than 10
seconds is indicative of an
unstable tear film
• If consistently breaks up
in the same location,
probably indicates a
defect in the corneal
epithelium

Clinical Correlation
• Congenital Dacryostenosis
– Approximately 50% of infants
are born without complete
canalization of duct
– approximately 4% are
symptomatic
– Symptoms:
• Lacrimation
• Discharge

– High incidence of recurrence

Clinical Correlation
• Congenital Nasolacrimal
Duct Obstruction
– By far the most common
congenital lacrimal
abnormality
– Usually due to an imperforate
valve of Hasner
– Could be transient
– Epiphora
– Irritation of the skin
– If not relief 4-8 weeks after
birth is considered probing

Clinical Correlation
Punctual Anomalies
• Atresia
– results if epithelization
or canalization fails to
reach the puncta
– Surgical exploration
often reveals an intact
canalicular system more
proximally

• Supernumerary puncta
are a form of fistula

Clinical Correlation
• Canaliculitis
– Infection of the
canaliculi
– Pain, swelling,
erythema and
discharge
– Frequently related to
an acute acinomyces
israelli infection
– Irrigation and probing
usually no effective
– Topical antibiotic or oral
if needed

Clinical Correlation
• Canaliculitis Drainage
– Acute canaliculitis with a
pouting puncta
– A posterior cut down of
the canaliculus and
curettage of the granules
from the system is done

Clinical Correlation
• Dacryoadenitis
– Is an inflammatory
enlargement of the
lacrimal gland
– acute or chronic
syndromes
– Usually infectious
etiology
– Pain, edema, erythema

Clinical Correlation
• Dacryocystitis
– Infection of the lacrimal
sac
– Usually for obstruction
of the nasolacrimal duct
– Acute or chronic
– Pain
– Edema
– Erythema
– Purulent discharge

Clinical Correlation
• Dacryocystorhinostomy
(DCR)

Tear Break Up Time
• http://www.youtube.com/watch?v=eSe8iz5Y2
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